Michaela Wirtz scite author profile

When optimizing the process parameters of the acidic ethanolic organosolv process, the aim is usually to maximize the delignification and/or lignin purity. However, process parameters such as temperature, time, ethanol and catalyst concentration, respectively, can also be used to vary the structural properties of the obtained organosolv lignin, including the molecular weight and the ratio of aliphatic versus phenolic hydroxyl groups, among others. This review particularly focuses on these influencing factors and establishes a trend analysis between the variation of the process parameters and the effect on lignin structure. Especially when larger data sets are available, as for process temperature and time, correlations between the distribution of depolymerization and condensation reactions are found, which allow direct conclusions on the proportion of lignin's structural features, independent of the diversity of the biomass used. The newfound insights gained from this review can be used to tailor organosolv lignins isolated for a specific application.

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Performance in (Ultra‐)high‐performance liquid chromatography—How to qualify and optimize instruments in practice

Jaekel

Wirtz

Lamotte

et al. 2023

J of Separation Science

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This paper investigates the suitability of an ultra‐high‐performance liquid chromatography/high‐performance liquid chromatography hybrid system for ultra‐high‐performance liquid chromatography applications. Thus, the effect of extra column band broadening, the gradient system, and the injection system were tested and optimized according to their capabilities. An increase of the theoretical plate number up to a factor of two is achieved by the optimization of the extra column volume into the typical ultra‐high‐performance liquid chromatography range (<10 μl). Moreover, for qualitative purposes injections of volumes typical for ultra‐high‐performance liquid chromatography methods are precise. Despite this, a lack of precision and accuracy was determined for the gradient system, and the dwell volume meets the typical specification range for conventional HPLC systems. Therefore, hybrid systems are the intercept between both spectra and are limitedly suitable for ultra‐high‐performance liquid chromatography applications. Another way to approximate ultra‐high‐performance liquid chromatography performance using a high‐performance liquid chromatography system is superficially porous particles. Thus, H/u curves of 5 μm superficially porous and 3 μm fully porous particles were recorded in order to determine the effect of the particle technology resulting in comparable performance of the used stationary phases.

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Michaela Wirtz

Beyond Yield Optimization: The Impact of Organosolv Process Parameters on Lignin Structure

Performance in (Ultra‐)high‐performance liquid chromatography—How to qualify and optimize instruments in practice

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